Scanning switch transistor for solid-state imaging device
A solid-state imaging device can improve a detection sensitivity of a signal detecting means by decreasing a parasitic capacity of a horizontal signal line. In a solid-state imaging device in which a plurality of pixels are arranged in a matrix fashion, a pixel signal is flowed through a horizontal switch (39) to a horizontal signal line (40) as a signal charge, and a signal is outputted by a signal detecting means connected to the end off the horizontal signal line (40), an insulating gate-type field-effect transistor comprising the horizontal switch (39) includes channels extended at least in two directions between its source electrode connected to the horizontal signal line (40) and other drain electrode.
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This a continuation of U.S. application Ser. No. 08/861,831 filed May 23, 1997 now U.S. Pat. No. 6,873,362 which a divisional of U.S. application Ser. No. 08/618,566 filed Mar. 20, 1996 now U.S. Pat. No. 5,825,056 which claims priority to Japanese Application No. P07-063 103 filed Mar. 22, 1995, all of which are incorporated herein by reference to the extent permitted by law.
BACKGROUND OF THE INVENTIONThe present invention relates to a solid-state imaging device, and more particularly to an amplifying type solid-state imaging device or a solid-state imaging device such as a MOS (metal oxide semiconductor) solid-state imaging device.
As a demand that a solid-state imaging device becomes high in resolution is increased, an internal amplifying type solid-state imaging device has hitherto been developed, and other MOS type solid-state imaging devices also have been known so far.
As the internal amplifying type solid-state imaging device, there are mainly known a static induction transistor (SIT), an amplifying type MOS imager (AMI), a charge-modulation device (CMD), and various imaging device structures such as a BASIS (base-stored image sensor) using bipolar transistors as pixels.
The following amplifying type solid-state imaging device is known as one of such internal amplifying type solid-state imaging devices. This amplifying type solid-state imaging device accumulates photoelectrically-converted holes (signal charges) in a p-type potential well in an n-channel MOS transistor (pixel MOS transistor), and outputs the change of channel current based on a potential fluctuation (i.e., potential change in back gate) in the p-type potential well as a pixel signal.
On the other hand the assignee of the present application has previously proposed a capacity loaded operation system amplifying type solid-state imaging device in which a sensitivity can be made uniform, a high resolution can be made, and a low power consumption can be realized.
A load capacity element 8 for holding a signal voltage (electric charge) is connected through an operation MOS switch 7 to the vertical signal line 5. An operation pulse φOP is applied to the gate of the operation MOS switch 7. The load capacity element 8 is connected to the drain of a horizontal MOS switch 9, and the source of this horizontal MOS switch 9 is connected to a horizontal signal line 10.
In
A signal detecting means, in this example, a charge detecting circuit 16 comprising an operational amplifier 14 using an inverting amplifier, e.g., a differential amplifier, a detection capacity element 14 and a reset switch 15 is connected to the output terminal of the horizontal signal line 10.
Specifically, the horizontal signal line 10 is connected to an inverting input terminal of the operational amplifier 13 of the charge detecting circuit 16, and a predetermined bias voltage VB is applied to a non-inverting input terminal of the operational amplifier 13. This bias voltage VB is used to determine the potential of the horizontal signal line 10. The detection capacity element 14 is connected in parallel to the operational amplifier 13, i.e., the detection capacity element 14 is connected between the inverting input terminal of the operational amplifier 13 and an output terminal t1, and a reset switch for resetting the horizontal signal line 10 and the detection capacity element 14, e.g., MOS transistor 15 is connected in parallel to the detection capacity element 14.
In this amplifying type solid-state imaging device 1, during the horizontal blanking period where reading operation is carried out, vertical scanning signals (i.e., vertical selection pulses) φV [φV1, . . . φVn, φVn+1, . . . ] are sequentially applied to the scanning lines 4 of every row from the vertical scanning circuit 3 to sequentially select the pixel MOS transistors 7 of every column. Also, when the operation MOS switch 7 is turned on by the operation pulse φOP, the pixel MOS transistor 2 and the load capacity element 8 are turned on so that a signal charge is started being charged in the load capacity element 8 from the moment the operation MOS switch 7 is turned on. When the operation MOS switch 7 is turned off after the signal voltage is stabilized sufficiently, a signal voltage corresponding to a channel potential corresponding to the amount of signal charges (amount of holes) accumulated in the pixel MOS transistor 2 is held in the load capacity element 8.
The signal voltage held in the load capacity element 8 is flowed to the horizontal signal line 10 as electric charge when the horizontal MOS switches 9 are sequentially turned on by the horizontal scanning signals (i.e., horizontal scanning pulses) φH [φH1, . . . φH1, φHi+1, . . . ] supplied thereto from the horizontal scanning circuit 11 during the horizontal scanning period.
The signal charge flowed to the horizontal signal line 10 is demodulated to the detection capacity element 14 of the charge detecting circuit 16 using the operational amplifier 13 as a signal voltage, and is then outputted to the output terminal t1 as a video signal.
The detection capacity element 14 of the charge detecting circuit 16 turns on and resets the reset switch 15 by a reset pulse φR before the horizontal MOS switch 9 corresponding to the next pixel MOS transistor is turned on.
According to the amplifying type solid-state imaging device 1, when the signal voltage is held in the load capacity element 7, substantially no current is flowed to the vertical signal line 5 so that a uniform sensitivity can be obtained without being affected by a resistance of the vertical signal line 5 very much.
Further, since the load is the capacity element 7, signal charges cannot be fluctuated less unlike the load MOS transistor, and hence a vertical stripe-shaped fixed pattern noise (FPN) is difficult to be generated.
Further, since the channel potential of the pixel MOS transistor 2 becomes a potential held in the load capacity element 8 as it is, a sensitivity can be increased as compared with the case that the pixel MOS transistor is operated in the stationary state by the load MOS transistor, i.e., under the condition that a constant current is flowed to the channel.
Furthermore, a steady-state current is not flowed to the pixel MOS transistor 2, a power consumption can be decreased.
As the horizontal MOS switch 9 of this amplifying type solid-state imaging device 1, there is used a MOS transistor of which the structure is illustrated in
In the MOS transistor 9, a source region 22S and a drain region 22D are formed on semiconductor regions separated by a field insulating layer (so-called LOCOS oxide layer) 21 provided by selective oxidation, and a gate electrode 23 made of polycrystalline silicon, for example, is formed between the source region 22S and the drain region 22D through a gate insulating film.
The gate electrode 23 is connected to the horizontal scanning circuit 11. A source electrode 24 and a drain electrode 24D are each made of Al, for example, and the drain electrode 24D is connected to the vertical signal line 5 through the operation MOS switch. The source electrode 24S is connected to the horizontal signal line 10. In
With the above-mentioned arrangement, since the source regions 22S of many horizontal switches 9 are connected to the horizontal signal line 10, a parasitic capacity of the horizontal signal line 10 is increased, thus lowering a detection sensitivity of the charge detecting circuit 16.
SUMMARY OF THE INVENTIONIn view of the aforesaid aspect, it is an object of the present invention to provide a solid-state imaging device wherein a detection sensitivity can be improved by decreasing a parasitic capacity of a horizontal signal line.
According to an aspect of the present invention, there is provided a solid-state imaging device which is comprised of a plurality of pixels, a plurality of vertical signal lines connected to the plurality of pixels, a plurality of horizontal switches disposed at every vertical signal line, the horizontal switch being composed of an insulating gate type FET (field-effect transistor) having first and second main electrodes, and the main electrode being connected to the vertical signal lines, a horizontal signal line connected to the second main electrode of the horizontal switch, and a signal detector connected to the horizontal signal line for detecting a signal obtained from the pixels, wherein the horizontal switch has channels formed in at least two directions between the first and second main electrodes.
According to other aspect of the present invention, there is provided a solid-state imaging device which is comprised of a plurality of pixels each generating a signal corresponding to an amount of incident light, a signal detector for detecting a signal obtained from the pixel, and a switch composed of an insulating gate-type FET (field-effect transistor) having a channel formed between first and second main electrodes, the first main electrode being connected to the pixel, and the second main electrode being connected to the signal detector, wherein the switch is arranged such that an area of the first main electrode in contact with the channel is larger than an area of the second main electrode in contact with the channel.
In accordance with a further aspect of the present invention, there is provided a solid-state imaging device which is comprised of a plurality of pixels each generating an electrical signal corresponding to an amount of incident light, a capacity connected to the pixel for accumulating signal charges of an amount corresponding to the electrical signal, a signal charge detector for detecting signal charges accumulated in the capacity, and a switch composed of an insulating gate-type FET (field-effect transistor) having a channel between first and second main electrodes, the first main electrode being connected to the capacity, and the second main electrode being connected to the signal charge detector, wherein the switch is arranged such that an area of the first main electrode in contact with the channel is larger than an area of the second main electrode in contact with the channel.
Prior to describing the present invention, the principle of the present invention will be summarized below.
A solid-state imaging device according to the present invention is a solid-state imaging device wherein a plurality of pixels area arranged in a matrix fashion, signals of pixels are supplied through horizontal switches to horizontal signal lines as signal charges, and a signal detecting means connected to the end of the horizontal signal lines outputs a signal. An insulating gate-type field effect transistor comprising the horizontal switch is arranged such that a channel between first and second main electrodes connected to the horizontal signal line thereof is formed at least in two directions.
In a solid-state imaging device according to the present invention, horizontal switches corresponding to pixels adjacent in the horizontal directions can be disposed in the upper and lower direction across the horizontal signal line.
In a solid-state imaging device according to the present invention, the solid-state imaging device includes a plurality of horizontal signal lines and wherein horizontal switches corresponding to pixels in horizontal lines can be distributed on respective horizontal signal lines.
In a solid-state imaging device according to the present invention, the solid-state imaging device includes a plurality of signal lines and wherein horizontal switches corresponding to pixels in horizontal lines can be distributed on respective horizontal signal lines and further disposed in the upper and lower direction across each horizontal signal line.
A solid-state imaging device according to the present invention will hereinafter be described with reference to the drawings.
The solid-state imaging device shown in
A load capacity element 38 for holding a signal voltage (electric charge) is connected to each vertical signal line 35 through an operation MOS switch 37. Specifically, the load capacity element 38 is connected between the vertical signal line 35 and a first potential, e.g., ground potential in this embodiment, and the operation pulse φOP is applied to the gate of the operation MOS switch 37. The load capacity element 38 is connected to the drain of a horizontal switch, i.e., an insulating gate type field-effect transistor (hereinafter referred to as a “horizontal MOS switch”) 39, and the source of the horizontal MOS switch 39 is connected to a horizontal signal line 40.
Reference numeral 41 denotes a horizontal scanning circuit comprising a suitable means such as a shift register. The horizontal scanning circuit 41 sequentially supplies the horizontal scanning pulses φH [φH1, . . . φHi, φHi+1, . . . ] to the gates of the horizontal MOS switches 39 connected to the horizontal signal line 40.
To the output end of the horizontal signal line 40 is connected a signal detecting means, e.g., a charge detecting circuit 46 which comprises an operational amplifier 43 using an inverting amplifier, e.g., a differential amplifier, a detection capacitor element 44 and a reset switch 45.
Specifically, the horizontal signal line 40 is connected to an inverting input terminal of the operational amplifier 43 in the charge detecting circuit 46, and a predetermined bias voltage VB is applied to a non-inverting input terminal of the operational amplifier 43. The bias voltage VB is used to determined a potential of the horizontal signal line 40. The detection capacitor element 44 is connected in parallel to the operational amplifier 43, i.e., between the inverting input terminal of the operational amplifier 43 and an output terminal t2, and the reset switch 45 which resets the horizontal signal line 40 and the detection capacitor element 44 is connected in parallel to the detection capacitor element 44.
The reset switch 45 is composed of a MOS transistor, for example, and a reset pulse φR is applied to the gate of the reset switch 45.
The operational amplifier 43 should preferably be composed of a MOS transistor because no input current is flowed to the MOS transistor or an input impedance of the MOS transistor is high.
In
An n-type source region 55 and a drain region 56 are formed on the p-type well region 53, and a gate electrode 58G made of polycrystalline silicon thin film is formed between the two regions 55 and 56 through a gate insulating film 57. The holes 54 that were accumulated in the p-type well region 53 located under the gate electrode 58G by photoelectric conversion are used to control a channel current (drain current) upon reading operation, and the changed amount of channel current becomes a signal output.
The gate electrode 58G is connected to the vertical scanning line 34, a drain electrode 58D is connected to the power supply source VDD, and a source electrode 58S is connected to the vertical signal line 35.
In the amplifying type solid-state imaging device 31, when the operation MOS switch 37 with a drain connected to the vertical signal line 35 is turned on by application of the operation pulse φOP to the gate thereof, a signal voltage from the pixel MOS switch transistor 32 is read out to the load capacity element 38 during the first half of horizontal blanking period HBK. The load capacity element 38 is held at a potential, i.e., voltage corresponding to a channel potential corresponding to an amount of signal charges accumulated in each pixel MOS transistor 32. The signal voltage read out to the load capacity element 38 turns on the horizontal MOS switches 39, which are sequentially scanned by the horizontal scanning circuit 41, during a horizontal video period, and outputted to the horizontal signal line 40.
More specifically, the vertical scanning pulses φV [φV1, . . . φVn, φVn+1, . . . ] from the vertical scanning circuit 33 are sequentially applied to the scanning lines 34 of respective rows, and the pixel MOS transistors 32 of respective rows are scanned sequentially. When the potential of the vertical scanning pulse φVn applied to the scanning line 34 of nth row, for example, goes to high level, the pixel MOS transistor 32 of nth row is placed in the selection state. The potential of the scanning line 34 corresponding to the non-selection goes to low level, and hence other pixel MOS transistor 32 that is connected to this scanning line 34 is placed in the non-selection state.
When the operation MOS switch 37 is turned on by the operation pulse φOP, the pixel MOS transistor 32 of nth row is energized, and a signal is developed at the terminal of the load capacity element 38 in response to an amount of signal charges (holes) accumulated in the amount of light incident on the pixel MOS transistor 32. Then, when the operation MOS switch 37 is turned off during the horizontal blanking period HBK, a signal voltage corresponding to the channel potential of the pixel MOS transistor 32 is held in the load capacity element 38. This operation is referred to as “capacitor load operation”, and is generally carried out during the horizontal blanking period HBK.
The signal charge (electric charge) held in the load capacity element 38 from the pixel MOS transistor 32 when the capacitor load operation is carried out during the horizontal blanking period HBK is sequentially flowed to the horizontal signal line 40 as signal charges because the horizontal MOS switches 39 are sequentially turned on by the horizontal scanning pulses φH [φH1, . . . φHi+1, . . . ] (shown in
The signal charge flowed to the horizontal signal line 40 is demodulated to the detection capacitor element 44 of the charge detecting circuit 46 using the operational amplifier 43 as a signal voltage, and then outputted to the output terminal t2 as a video signal.
The detection capacitor element 44 in the charge detecting circuit 46 turns on and resets the reset switch 45 by the reset pulse φR before the horizontal MOS switch 39 corresponding to the next pixel MOS transistor 32 is turned on. By this reset operation, the horizontal signal line 40 and a voltage across the detection capacitor element 44 are reset to the bias voltage VB. Specifically, after the horizontal MOS switch 39, for example, has been turned on and the signal output of the pixel MOS transistor 32 has been developed at the output terminal t2, when the reset switch 45 is turned on, the detected capacity of the charge detecting circuit 44 is reset, initializes the detection capacity, and becomes ready for detecting the signal output of the next pixel MOS transistor 32.
According to this embodiment, as shown in
In the horizontal MOS switch 39 shown in
A source electrode 63S made of Al, for example, connected to the source region 62S is connected to the horizontal signal line 40, and drain electrodes 63D1, 63D2 made of Al, for example, connected to the drain regions 62D1, 62D2 are connected to the common vertical signal line 35. In
In this horizontal MOS switch 39, the drain regions 62D1, 62D2 are disposed across the source region 62S in an opposing relation to each other, and the channel between the source and drain is formed in the two directions. In other words, the area of the source region 62S is reduced to about ½ of that obtained in the comparative example shown in
The amount of signal charges developed at the output terminal t2 of the charge detecting circuit 46 greatly depends on a parasitic capacity CB of the horizontal signal line 40.
Specifically, in the equivalent circuit shown in
In the above equation (1), since the parasitic capacity CB of the horizontal signal line 40 occupies most of the source capacity of the horizontal MOS switch 39, if the parasitic capacity CB is reduced, then a sensitivity of the solid-state imaging device can be improved.
According to the solid-state imaging device 31 according to this embodiment shown in
Having compared a source capacity Csource of the embodiment shown in
However, as shown in
In the calculation of specific example, Cj=5×10−4 F/m2, Cjsw=3×10−10 F/m, Cgso=1×10−10 F/m, W=10 μm, and LD=2 μm.
Assuming now that 80% of the parasitic capacity of the horizontal signal line is occupied by the source capacity of the horizontal MOS switch, then when the horizontal MOS switch 39 of the embodiment shown in
By way of example, if the capacity CL of the load capacity element 38 (8) is 1 pF, the capacity Cn of the detection capacity element 44 (14) is 1 pF, the parasitic capacity CB of
In actual practice, if the parasitic capacity CB of the horizontal signal line 40 is decreased, then the channel width of the horizontal MOS switch 39 may be reduced concurrently therewith. Therefore, the source capacity of the horizontal MOS switch 39 is decreased, and hence a sensitivity can be improved much more.
Since the horizontal MOS switch 39 according to this embodiment includes two drains and two gates for one source, the width of the horizontal MOS switch 30 in the horizontal direction is increased. As a result, it is frequently observed that one horizontal MOS switch cannot be inserted into the horizontal pitch of the pixel MOS transistor 32.
In the second embodiment, horizontal MOS switches 30 corresponding to pixel MOS transistors 32 adjacent in the horizontal direction are disposed across one horizontal signal line 40 in the upper and lower directions. Specifically, each horizontal MOS switch corresponding to every other pixel MOS transistor 32 in the horizontal direction is disposed above the horizontal signal line 40 and connected to the horizontal signal line 40, and each horizontal MOS switch 39 corresponding to another every other pixel MOS transistor 32 is disposed under the horizontal signal line 40 and connected to the horizontal signal line 40.
A structure of the horizontal MOS switch 39 is the same as that shown in
Specifically, the horizontal MOS switches 39 corresponding to every other pixel MOS transistors 32 in the horizontal direction and the horizontal MOS switches 39 corresponding to another every other pixel MOS transistors 32 are disposed in two stages. The horizontal MOS switches 39 in the first stage are connected to the first horizontal signal line 40A, and the horizontal MOS switches 39 in the second stage are connected to the second horizontal signal line 40B.
A transistor structure of the horizontal MOS switch is similar to that of
Ends of the two horizontal signal lines 40A, 40B may be connected electrically, and may be inputted to one charge detecting circuit 46 or each charge detecting circuit 46 may be connected to the horizontal signal lines 40A, 40B (so-called two-line output). In this embodiment, charge detecting circuits 46A and 46B are connected to the horizontal signal lines 40A and 40B, respectively.
According to this embodiment, even when the horizontal pitch of the pixel MOS transistor 32 is narrower than the width of the horizontal MOS switch 39, the horizontal MOS switches can be arranged, and the solid-state imaging device according to the present invention can be suitable for high-density packing. If the charge detecting circuit 46 is prepared for each of the horizontal signal lines 40 [40A and 40B], then a clock frequency of the horizontal scanning circuit 41 can be lowered to the half, and hence the frequency characteristic of the charge detecting circuit 40 can be lowered, thereby making it possible to improve an S/N (signal-to-noise ratio).
The layout pattern according to this embodiment is a combination of the layout patterns of
The horizontal MOS switches 39 disposed in the upper and lower directions of the first horizontal signal line 40A are connected to the first horizontal signal line 40A, and the horizontal MOS switches 39 disposed in the upper and lower directions of the second horizontal signal line 40B are connected to the second horizontal signal line 40B. The gates of the horizontal MOS switches 39 disposed above the first and second horizontal signal lines 40A and 40B are connected in common, and further connected to the horizontal scanning circuit 41. The gates of the horizontal MOS switches 39 disposed under the first and second horizontal signal lines 40A and 40B are connected in common, and further connected to the horizontal scanning circuit 41. The structure of the horizontal MOS switch 39 is the same as that of
The ends of the two horizontal signal lines 40A and 40B may be connected electrically, and inputted to one charge detecting circuit 46. Alternatively, each charge detecting circuit 46 may be connected to the two horizontal signal lines 40A and 40B. In this embodiment, charge detecting circuits 46A and 46B are connected to the two horizontal signal lines 40A and 40B.
According to the layout pattern of this embodiment, the solid-state imaging device can be applied to the case that the horizontal pitch of the pixel MOS transistor is further narrowed.
According to the above embodiment, since the source capacity of the horizontal MOS switch 30 connected to the horizonal signal line 40 is decreased considerably, a detection sensitivity can be increased. In other words, the gain of the charge detecting circuit 46 can be increased, and hence the S/N ratio can be improved.
While the horizontal MOS switch 39 has such transistor structure that the drain regions 62D1, 62D2 are disposed at both sides of the central source region 62S to provide the channels in the two directions as described above, the principle of the present invention can also be applied to other transistor structures shown in
In a horizontal MOS switch 39 shown in
In a horizontal MOS switch 39 shown in
In a horizontal MOS switch 39 shown in
In case the horizontal MOS switches 39 have the transistor structures shown in
While the amplifying type solid-state imaging device according to the present invention uses the charge detecting circuit 46 as the signal detecting means connected to the horizontal signal line, the present invention is not limited thereto, and a signal charge may be reconverted by an amplifier with a base grounded or a load resistor into a voltage.
Further, while the present invention is applied to the capacitor load operation system amplifying type solid-state imaging device, the principle of the present invention can also be applied to other amplifying type solid-state imaging device and MOS type solid-state imaging device, etc.
According to the solid-state imaging device of the present invention, the source capacity of the horizontal switch connected to the horizontal signal line can be decreased considerably, and hence the detection sensitivity, i.e., gain of the signal detecting means can be increased, thereby improving the S/N.
According to the solid-state imaging device of the present invention, when the horizontal switches corresponding to the pixels adjacent in the horizontal direction are disposed in the upper and lower direction across the horizontal signal line, the horizontal pitch of the pixels can be narrowed.
Further, according to the solid-state imaging device of the present invention, since the horizontal switches having a plurality of horizontal signal lines and which correspond to horizontal pixels are distributed to and connected to respective horizontal signal lines, even when the horizontal pitch of pixels is narrower than the width of horizontal switch, the horizontal switches can be arranged.
Furthermore, according to the solid-state imaging device of the present invention, when the horizontal switches having a plurality of horizontal signal lines and which correspond to the pixels of horizontal line are distributed to and connected to a plurality of horizontal signal lines and disposed in the upper and lower directions across each horizontal signal line, even if the horizontal pitch of pixels is further narrowed, then horizontal switches can be arranged.
Having described preferred embodiments of the invention with reference to the accompanying drawings, it is to be understood that the invention is not limited to those precise embodiments and that various changes and modifications could be effected therein by one skilled in the art without departing from the spirit or scope of the invention as defined in the appended claims.
Claims
1. A solid-state imaging device comprising:
- a plurality of pixels;
- a plurality of vertical signal lines connected to said plurality of pixels;
- a plurality of horizontal switches disposed at every vertical signal line, each of said horizontal switches being composed of an insulating gate type FET (field-effect transistor) having first and second main electrodes, said first main electrode being connected to said vertical signal lines and being formed from first and second drain regions located at opposite sides of a source region of said FET, said FET further having a channel formed in first and second channel directions between said first and second main electrodes, said first channel direction being between said source region and said first drain region, and said second channel direction being between said source region and said second drain region;
- a horizontal signal line connected to said second main electrode of said horizontal switch; and
- a signal detector connected to said horizontal signal line for detecting a signal obtained from said pixels;
- wherein said horizontal signal line is divided into a first horizontal signal line and a second horizontal signal line, and said horizontal switch includes a first horizontal switch group connected to said first horizontal signal line and a second horizontal switch group connected to said second horizontal signal line, and
- wherein a first signal from one of adjacent two of said pixels in a horizontal direction is output to said first horizontal switch group and second signal from the other of said adjacent two of said pixels is output to said second horizontal switch group.
2. A solid-state imaging device according to claim 1, wherein a signal is supplied to said horizontal signal line in the form of a signal charge.
3. A solid-state imaging device according to claim 2, wherein said signal detector includes an operational amplifier, said horizontal signal line is connected to a first input terminal of said operational amplifier, a second input terminal of said operational amplifier is supplied with a predetermined bias voltage, and a detection capacity element is connected in parallel to said operational amplifier.
4. A solid-state imaging device according to claim 1, wherein said pixel is composed of a MOSFET (metal oxide field-effect transistor).
5. A solid-state imaging device according to claim 1, further comprising a load capacitor one end of which is connected to a fixed potential and whose other end is connected to said vertical signal line.
6. A solid-state imaging device according to claim 1, wherein said horizontal switch is disposed in said horizontal signal line at its side of said pixel, and said horizontal switch is disposed in said horizontal signal line at its side opposite to said pixel.
7. A solid-state imaging device according to claim 1, wherein said horizontal signal line is divided into two horizontal signal lines, and said horizontal switch includes a first switch group connected to one of said divided horizontal signal lines and a second horizontal switch group connected to the other of said divided horizontal signal lines.
8. A solid-state imaging device according to claim 7, said first switch group are on the side of said pixel above one of said divided horizontal signal lines, and said second switch group are disposed between said divided two horizontal signal lines.
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Type: Grant
Filed: Mar 28, 2005
Date of Patent: Dec 30, 2008
Patent Publication Number: 20050168609
Assignee: Sony Corporation (Tokyo)
Inventor: Kazuya Yonemoto (Tokyo)
Primary Examiner: Lin Ye
Assistant Examiner: Chriss S Yoder, III
Attorney: Sonnenschein Nath & Rosenthal LLP
Application Number: 11/091,150
International Classification: H04N 5/335 (20060101);